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Chapter 18 “Acids, Bases and Salts”

Chapter 18 “Acids, Bases and Salts”. Some familiar chemistry…. THW (04/06). Chapt. 18 OBJECTIVES. State and use the Arrhenius and Br ø nsted-Lowry definitions of acids and bases. Identify common physical and chemical properties of acids and bases.

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Chapter 18 “Acids, Bases and Salts”

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  1. Chapter 18 “Acids, Bases and Salts” Some familiar chemistry…. THW (04/06)

  2. Chapt. 18 OBJECTIVES • State and use the Arrhenius and Brønsted-Lowry definitions of acids and bases. • Identify common physical and chemical properties of acids and bases. • Describe dissociation constants and explain what they indicate about acids and bases. • Use experimental data to determine dissociation constants. • Explain what most ‘acidic hydrogen atoms’ have in common. • Explain wghat most bases have in common. • Describe nomenclature of acids and bases.

  3. 18-1 Defining Acids and Bases • What are some properties of acids and bases? (Let’s derive some.) • Taste (Don’t do this at home!) • Touch (Or this!) • Reactions with metals • Electrical conductivity • Reactions with “Indicators” • Neutralization

  4. The Arrhenius Definitions • Acid – a substance that dissociates in water to produce hydrogen ions (H+). • Base – a substance that dissociates in water to produce hydroxide ions (OH-). • See Fig. 18-6 (page 599). • Arrhenius acids and bases react together (neutralize) to form a salt and water. • Examples

  5. The Brønsted-Lowry Definiton • Arrhenius definition is restrictive • Applies only to water solutions. • Does not explain why covalent molecules are acids (HCl, HBr) • Does not explain why certain compounds like NH3 are bases. • Brønsted-Lowry Definitions • Acid: a proton (H+) donor. • Base: a proton acceptor.

  6. The Hydronium Ion • Protons (H+) do not really exist in water solutions in this way. • HydroniumIons (H3O+) are a better approximation of what occurs.

  7. Conjugate Acid-Base Pairs • The difference between an acid and a base may be as simple as one H+ ion! • To emphasize this relationship, chemists use the terms ‘conjugate acid – conjugate base’ pairs. • The term “conjugate” means “joined together.” • Conjugate Acid-Base Pair is two compounds that differ by only one H+ ion. • Examples (Fig. 18-12, page 603).

  8. 18-2 Determining The Strengths of Acids and Bases • Strong and Weak Acids • Strong acids easily lose H+ ions, so they are strong electrolytes (high degree of dissociation). • Weak acids do not dissociate very much. • Strong and Weak Bases • Strong bases (such as compounds with OH-) have high affinity for H+ ions, and they are strong electrolytes. • Weak bases react partially with water to form hydroxide ions. • Use single arrows () to signify strong acids (~100% dissociation). (HCl) • Use double arrows (↔) to signify weak acids (low amount of dissociation). (HC2H3O2) • Strength of Conjugate Acid-Base Pairs • The stronger the acid, the weaker its conjugate base. • The stronger the base, the weaker its conjugate acid.

  9. The Acid Dissociation Constant • For the reaction HA (aq) + H2O (l) ↔ H3O+ (aq) + A- (aq) we may write an equilibrium expression: Keq = [H3O+][A-] / [HA][H2O] or Ka = [H3O+][A-] / [HA] (Why?) where Ka is the acid dissociation constant. The larger the Ka, the stronger the acid. Example

  10. The Base Dissociation Constant • For the reaction B (aq) + H2O (l) ↔ HB+ (aq) + OH- (aq) we may write an equilibrium expression: Keq = [HB+][OH-] /[B][H2O] or Kb = [HB+][OH-] /[B] (Why?) where Kb is the base dissociation constant. The larger the Kb, the stronger the base. Example

  11. Calculating Dissociation Constants • This is a very easy task once the concentrations of ions are known. • Sample problem (p612).

  12. Acid-Base Properties of Salts • Salts are strong electrolytes, forming cations and anions in water. • Many of these ions are weak Brønsted-Lowry acids or bases, so they produce H+ or OH-. • This is called a ‘salt hydrolysis reaction.’

  13. Types of Salt Hydrolysis Reactions • Salts of Strong Acids & Strong Bases • Solution is neutral. • Salts of Strong Acid & Weak Bases • Solution is acidic. • Salts of Weak Acids & Strong Bases • Solution is basic (alkaline). • Salts of Weak Acids & Weak Bases • Not easily predicted due to the many complex equilibria involved.

  14. 18-3 Naming and Identifying Acids and Bases • Acids have “acidic hydrogens.” • These have a slight positive charge while still part of the molecule. • Binary Acids • Oxy Acids • Carboxylic Acids • Bases • These always contain an unshared pair of electrons. • Anions • Amines • Nomenclature (See p619 and prior notes.)

  15. Chapt. 18 OBJECTIVES • State and use the Arrhenius and Brønsted-Lowry definitions of acids and bases. • Identify common physical and chemical properties of acids and bases. • Describe dissociation constants and explain what they indicate about acids and bases. • Use experimental data to determine dissociation constants. • Explain what most ‘acidic hydrogen atoms’ have in common. • Explain what most bases have in common. • Describe nomenclature of acids and bases.

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